Multifunctional interconnection system for an electronic cabinet and cabinet comprising such a system

ABSTRACT

An electric cabinet provided with an interconnection system for devices such as computers received in the cabinet. The interconnection system includes at least one waveguide forming part of the frame of the cabinet. The waveguide is provided with openings disposed facing housings for receiving the aforementioned devices. The openings being dimensioned to form a barrier to the passage of radio-frequency wireless communication waves to be transmitted through the waveguide and to form a barrier to external waves.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a multifunctional interconnection system for an electronic cabinet, notably an electronic cabinet of aircraft electrical or electronic enclosure type and a cabinet comprising such a system.

It applies notably for the cabinets for electronic equipment items such as, for example, the cabinets that group together the computers present in the airplanes.

2. Technological Background

In current aircraft, and notably for maintenance and accessibility reasons, the computers are grouped together in electrical enclosures.

The enclosures, also called electrical or avionics racks, have three main functions. An interconnection function: to connect the computers grouped together in the enclosure between the equipment items and with the apparatus for exchanging data and electrically powering these computers.

A mechanical function: to hold the computers of the apparatus in position.

A cooling function: the system for cooling the apparatus is directly connected thereto such that cold air circulates in the shelves of the enclosure to directly cool the computers while hot air is also extracted by these shelves.

The technology used for the connections is of the electrical wiring type by means of standardized connectors (connectors known by the acronym ARINC) which are heavy and bulky.

Some links use optical fiber but these connections are few in number.

Each computer is linked to the equipment items of the aircraft by means of a standard connector for example of ARINC 600 type, that is to say a connector with 600 points of connecting and the wiring is of point-to-point type.

More often than not, all of the points of contact of the connector are not used and approximately 30 to 40% of the connection capacity of the connector is used which results in obvious loss of space, excess weight and excess cost.

Furthermore, each change of configuration of the architecture of the computer network leads to a wiring modification procedure that is difficult and costly in terms of time.

For example, for an enclosure or rack of average size for an average civilian mail airplane, the total weight of the cables, of the cable supports and of the connectors is approximately 80 kg whereas the weight of the mechanical structure is close to 70 kg. Thus, the interconnection represents more than 50% of the overall weight of the rack.

The current interconnection solutions in the aircraft are therefore mainly three-dimensional wired networks and all of the wiring is located at the computers in the electrical enclosures.

Trial production of devices for wireless communication between a number of equipment items and using waveguides exist, the document U.S. Pat. No. 8,078,215 for example proposes a waveguide solution comprising a number of points of connection and the document US2010/0318243 proposes using airplane structural parts, the stringers, as waveguide.

BRIEF DESCRIPTION OF THE INVENTION

In light of this prior art, the concept of the present invention is based on a radiofrequency wireless communication system and on a multifunctional structure comprising a waveguide for the communication system.

For this, the present invention proposes an electrical enclosure provided with an interconnection system for equipment items such as computers accommodated in said enclosure, characterized in that the interconnection system comprises at least one waveguide forming part of the framework of the enclosure, said waveguide being provided with holes arranged facing housings for accommodating said equipment items, said holes being dimensioned to form a screen to the passage of wireless communication radiofrequency waves to be transmitted by said waveguide and form a screen to external waves.

Advantageously, said at least one waveguide further constitutes a ventilation duct for equipment items of said enclosure, at least some of said holes comprising holes for the passage of air.

According to a particular embodiment, the enclosure comprises invariant interfaces for the equipment items arranged in the enclosure.

Advantageously, said at least one waveguide is configured to serve also as grounding link and/or as functional current return element for the equipment items which are linked thereto.

According to a particular embodiment, the enclosure comprises a mechanical structure supporting equipment items of which at least some elements are metallic and are used as conductors for transporting electrical power supply for said equipment items.

The connection between these conductor elements and the equipment items is advantageously made by flat contacts in order to obviate the constraints of alignment between the equipment items and the enclosure.

The interconnection system of the invention advantageously has an architecture based on a standardized topology and on communication protocols of digital network type.

According to a particular embodiment, the interconnection system comprises transceivers provided with antennas that are inserted into at least some of said holes of the waveguides so as to link the equipment items to the network.

The transceivers are advantageously identical for all the equipment items of the enclosure such that their connection to the network is an invariant.

The wired links to the remote equipment items arranged in the aircraft are advantageously grouped together at an enclosure input/output equipment item comprising a router function for the wireless link.

The enclosure comprising shelves, these shelves preferably have a waveguide function.

According to one embodiment, the shelves are divided into at least two hollow sections, at least one first section being configured to supply cold air to the equipment items borne by the enclosure and to form a waveguide conveying the wireless communication, at least one second section being adapted to extract hot air from the equipment items.

Advantageously, at least one of said sections conveys the electrical power supply for these equipment items.

According to a particular embodiment, the shelves comprise three sections, a central section configured to supply cold air to the equipment items borne by the enclosure and convey the wireless communication, two lateral sections adapted to extract hot air from the equipment items. More particularly, the central section is advantageously configured to constitute a current return for the equipment items.

Advantageously, at least one of the lateral sections conveying an electrical power supply for the equipment items.

The multifunctional structure is designed to ensure a secure interconnection between the equipment items of an enclosure, provide the electrical power supply, ensure that the equipment items are fixed and held in position, provide cold air to the equipment items and extract hot air therefrom.

The wireless communication uses, for example, a network communication protocol and is distributed to the equipment items of the enclosure.

A multiplexing of the transmitted data is possible.

The solution of the present invention simplifies the installation of the systems by eliminating most of the cables and their supports and shieldings.

Similarly, the multipin connectors are eliminated and replaced at the computers in the enclosure by antennas or transceivers and at the enclosure by holes for passage into the waveguides.

BRIEF DESCRIPTION OF THE DRAWINGS

Other features and advantages of the invention will be apparent on reading the following description of a nonlimiting exemplary embodiment of the invention with reference to the drawings which represent:

in FIG. 1: a rear view of an enclosure of avionics equipment items linked by electrical connectors of the prior art;

in FIG. 2: a schematic view of an electrical enclosure of the prior art;

in FIG. 3: a three-quarter front schematic view of a first exemplary embodiment of an enclosure according to the invention;

in FIG. 4: a three-quarter rear schematic view of the enclosure of FIG. 3;

in FIG. 5: a three-quarter front detail of the enclosure of FIG. 3;

in FIG. 6: a perspective schematic view of a second exemplary embodiment of an enclosure according to a variant of the invention;

in FIG. 7: a perspective view of a transverse section of the enclosure of FIG. 6;

in FIG. 8: a detail of the view of FIG. 7;

in FIG. 9: a diagram of the waveguide architecture of the invention;

in FIG. 10: a schematic view of an input/output equipment item for the invention;

in FIG. 11: a first exemplary embodiment of the invention with optical links;

in FIG. 12: a second exemplary embodiment of the invention with optical links.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

The invention relates firstly to an interconnection system based on a multifunctional enclosure structure and a wireless communication.

The prior art concerning avionics enclosures is represented in FIGS. 1 and 2.

FIG. 1 shows a detail of the rear of an enclosure a in which electrical connectors b1, b2 make it possible to link bundles of electrical cables c1, c2 to the computers arranged in the enclosure.

FIG. 2 shows an example of electrical wiring of such an enclosure and the complexity of such wiring c in parallel with the cooling devices e, f of the computers d can easily be seen.

The multifunctional structure 1, 3 of the present invention which applies to enclosures as represented in FIGS. 3 and 6 aims notably to simplify such enclosures and must ensure, in addition to the transporting of the communication between the computers in the enclosure and the rest of the aircraft, the electrical power supply and ventilation of the equipment items in the electrical or electronic enclosure.

The present invention proposes invariant interfaces between the equipment items arranged in the enclosures and the latter and an architecture based on a standardized topology and network-type communication protocols.

The basic principle is to simplify the interconnection within the enclosure by using wireless communications propagated in waveguides as represented in FIG. 10.

According to this figure, the wired links 23 to the remote equipment items arranged in the aircraft are grouped together at an enclosure input/output equipment item 22.

This input/output equipment item will incorporate the received data in computer frames transmitted to all the computers in the enclosure and switch the data transmitted by the computers in the enclosure to the equipment items concerned in the aircraft. For this, it comprises a plurality of analog/digital converters 25 and digital/analog converters 26 receiving and transmitting signals from and to wiring sets 23 a and 23 b linking the system to actuators and sensors of the aircraft. The input/output equipment item comprises a processor 27 adapted to transmit the digitized data between the converters and the computers 10 a, . . . 10 f of the enclosure according to a network protocol.

The input/output equipment item further comprises a communication module 24 adapted to transmit and receive via an antenna 11 in the waveguide 3 linking the input/output equipment item of the enclosure to the other equipment items 10 a, . . . , 10 f housed in said enclosure. The communication module operates notably as a router for the network protocol transmitted in the waveguide.

The interconnection within the enclosure uses a radiofrequency wireless communication conveyed by the waveguides 3 in the shelves accommodating the computers.

A wireless communication involves the use of remote transceivers which avoid the use of cables and of connectors.

The transceivers are advantageously the same for all the equipment items of the enclosure such that their connection to the network is an invariant. They comprise an antenna 11 inserted into holes of the waveguides 3 coming into contact with the equipment items 10 a, . . . , 10 f.

For the electrical power supply for these equipment items, power supply bars 71, 81 distribute the current in the enclosure.

The wireless network communication intrinsically allows for a simplified configuration and reconfiguration by enclosure software because the position of the equipment items of the enclosure is unimportant as long as it remains within the communication zone. The equipment items merely need to send and receive signals whatever their position, the identification of the data and the routing thereof are performed by software in the input/output equipment item.

Numerous wireless technologies and protocols exist and can be used and, for example, the WiFi communication protocol can be used because of its design simplicity. Other protocols and wavelengths are of course possible depending on the performance levels sought.

The use of wireless technologies for communication dictates a significant security level, an absence of outward emission of disturbances and a high order of robustness against disturbances from outside.

A use of the WiFi wireless communication protocol 802.11a with frequencies around 5 GHz makes it possible to have 24 channels with no overlap, each allowing a theoretical bit rate of 54 Mbit/s. Thus, 24 hosts can exchange data in the waveguide with no disturbance. If a number of hosts communicate over the same channel the bit rate is then divided by the number of hosts present on said channel. In the case of an average mail airplane rack of standard type, the most populated shelf supports 9 LRU computers (line replaceable computers). In the worst case, by using a WiFi 802.11a protocol with a single waveguide, a single communication channel will allow an available bandwidth per equipment item of 6 Mbit/s.

Other protocols such as, for example, the UWB protocol can be used to increase the efficiency of the system.

The interconnection system of the invention makes it possible to simplify the communication between the equipment items and the input/output equipment item because this communication is made within the waveguide 3 which makes it possible to insulate the communication from the external disturbances while avoiding, at the same time, having this communication disturb other external equipment items.

A first exemplary embodiment is described in FIGS. 3, 4 and 5.

FIG. 3 represents an enclosure 1 equipped with equipment items 10 of computer type on shelves 101. According to this example, and as represented more particularly in FIG. 4 vertical waveguides 3 a, 3 b and 3 c link the computers one above the other.

According to FIG. 5 in particular, the waveguide comprises holes 5 facing the rear of the equipment items 10 to receive antennas of the equipment items.

According to an advantageous embodiment of the invention which uses the hollow waveguides as ventilation ducts, the holes 5 serve as ventilation orifices in order to provide cool air to the equipment items.

Vertical bars 7 and 8 make it possible to deliver the electrical power supply for the computers through electrical contact zones 20 and 21.

The connection between these conductor elements and the equipment items is made for example by flat contacts on the bars and piston contacts of known type at the rear of the computers in order to minimize the stresses/tolerances of production and assembly of the structure (no alignment necessary) thus making it possible to eliminate heavy and costly mechanical elements.

For example, the electrical contacts between the enclosure and the computers can for example be flat contacts with plates as marketed by the company Multi-Contact.

The equipment items are fixed in the enclosure by conventional means that are not represented.

The bars 7 and 8 and the waveguides 3 a, 3 b, 3 c made of metallic material are here also structural elements of the enclosure which, as represented in FIG. 4, support the shelves through, here, fixing tabs 103 welded or fixed in any way onto the waveguides and screwed at the rear of the shelves 101, through brackets 102 fixed onto the power supply bars 7, 8 and onto which the lateral edges of the shelves are fixed.

As seen above, the hollow waveguides 3 are also used as ventilation duct for the various equipment items. Here, a horizontal waveguide 3 d links the waveguides 3 a, 3 b, 3 c and comprises a blown air input V.

The input/output equipment item is for example the equipment item 10 a top left in FIG. 4 which then comprises a bundle of cables schematically represented under the reference 104.

In this example, the air outlet for the equipment items is toward the outside.

The waveguides are also possibly configured to serve as functional current return element for the equipment items which are connected thereto.

The use of wireless communication between the electronic equipment items allows for an installation time saving but also makes it possible to notably reduce the weight because there are no longer numerous cables and connectors. The waveguides act as wiring while offering a better protection against interference and a greater modularity.

To add or remove a computer in the communication network, the only thing to be done, apart from the mechanical fixing or dismantling, is to position or remove its antenna on or from the waveguide and apply the power supply contacts onto the power supply bars.

Furthermore, because of the very low attenuation of the signal in the waveguides in the enclosure, a very low power is necessary for the network.

In an alternative embodiment, the cabinet for electrical equipment items of the invention is, according to FIG. 6, an enclosure 3 for which the waveguides are incorporated in shelves 40 bearing rows of equipment items 10.

This design is particularly suitable for producing compact enclosures and for optimizing the ventilation of the equipment items 10.

The shelves of the enclosure extend longitudinally over the entire width of the enclosure under the equipment items. They are divided transversely into sections adapted for different functions, at least one of these sections being used as waveguide.

According to FIGS. 6 to 8, three sections are produced. The central section 4 is dedicated to the cold air inlet, the wireless communication and a current return.

The sections 41 a, 41 b surrounding the central section are used to extract hot air from the computers and provide the electrical power supply to these computers.

These ducts 4, 41 a, 41 b are conductors of electricity and are for example insulated from one another by plastic rods or plates that are not represented.

They can also be coated with a thermal and electrical insulation material comprising holes in the computer coupling zones.

According to FIG. 8, the central section comprises holes 6 emerging under the equipment items 10 to receive the antennas 11, represented in FIG. 7, and holes 61 to allow cooling air to pass to the equipment items which are cooled from below in this case.

The apertures or holes 6, 61 are produced with a dimension less than a quarter of the wavelength λ/4 of the electromagnetic waves which can not therefore pass through these holes.

For 2.4 GHz WiFi, the wavelength is 12.5 cm. The diameter of the apertures is chosen to be less than 3 cm so that the apertures act as low-pass filter and do not allow the waves to pass.

According to FIG. 8 in particular, the equipment items 10 are arranged in cradles 106 comprising an open bottom to allow the passage of the antenna and of the air in the central section produced by the waveguide 4 and to make it possible to connect the power supply for the equipment item by means of electrical contacts 20, 21 arranged on the sections 41 a and 41 b on either side of the central section.

According to FIG. 7, the sections 41 a, 41 b are provided on their bottom face with apertures 106 for extracting air from the equipment items which are, for their part, provided with aeration holes 105 a, 105 b on the top face as represented in FIG. 8.

Obviously, the rectangular tube sections forming the shelves are assembled together through electrical insulation means, for example the cradles 106 which can be produced from non-conductive composite materials.

To return to FIG. 6, the lateral ends of the enclosures comprise coupling ducts 107, 108 for the ventilation and are provided with means for coupling the waveguides between the various shelf levels.

A rack architecture that is optimized for example by having input/output equipment items for each level can significantly increase the individual bandwidth by reducing the number of computers communicating over the same channel. The use of another protocol such as the UWB protocol for example can also increase the theoretical bandwidth for the complete system.

The invention thus provides flexibility in the production of the electronic enclosures or racks notably in aircraft by reducing the number of electrical connection points and cables which is favorable to the reliability of the systems and their weight. The invention also makes it possible to standardize and simplify the interface of the avionics equipment items which reduces the cost thereof.

The invention according to FIG. 9 is based on an input/output equipment item 22, for an electrical or electronic enclosure grouping together a plurality of equipment items such as computers.

According to FIG. 10, the input/output equipment item comprises a plurality of analog input/output paths 23 a, 23 b and conversion units consisting of analog/digital converters 25 and digital/analog converters 26, an input/output path of network port type 23 c and an optical input/output path 23 d.

The analog input paths comprise a formatting and/or protection step 251 upstream of the analog/digital converters 25 and the analog output paths of the power stages 261 at the output of the digital/analog converters 26.

The conversion units are linked to a computation unit 27 of microcomputer type comprising a microprocessor, mass memory, RAM memory and an internal program.

The equipment item further comprises a digital network link protocol management unit 27 a linked to the computation unit and to a transceiver module 24.

The input/output equipment item comprises software suitable for performing the transmission in digital form of data representative of input/output values from and to the network computers through the transceiver module.

The software can be of a type suited to passive transmission which merely transmits the input data with the number of the input on the network of the enclosure and assigns the output data to the outputs as determined by the computers, or be software suitable for transmitting dedicated frames for the computers of the enclosure and for retranscribing the output data on reception of standardized frames from the computers of the enclosure.

The software notably comprises a computer network management module through the transceiver module and operate as router for the network.

The input/output equipment item can also have a data server function for the equipment items or computers of the enclosure. It can constitute a protocol converter between the network internal to the enclosure and one or more networks of an aircraft.

The interconnection system of the enclosure can comprise a radiofrequency network confined in the waveguides associated with the enclosure and linking the transceiver modules of the computers and of the input/output equipment item. The interconnection system can alternatively comprise a network of optical waveguides associated with the enclosure and linking the optical modules of the computers and of the input/output equipment item.

The examples of FIGS. 11 and 12 are variant embodiments for which the communication between an input/output equipment item 222, 222 a or airplane rack converter, and the computers 210 is at least partly optical.

In the example of FIG. 11, the input/output equipment item 222 comprises two links 223 a, 223 b terminated by optical transceivers 224 for each to transmit and receive an optical beam on a level 201, 202 of an enclosure of the invention. The input/output equipment item in this case comprises two transceivers 225.

Each computer 210 itself comprises a pair of optical transceivers 225 a, 225 b which ensure the continuity of the two-way optical link 230 on each level of the enclosure between the computers.

In the case of FIG. 12, the rack/airplane converter input/output equipment item distributes one shelf 203 of the enclosure through a direct output 226 and two shelves 201, 202 through repeaters 211 linked to the input/output equipment item by a two-way optical link 212. The input/output equipment item in this case comprises three transceivers 226.

Such a system uses the ventilation ducts 3, 3 a, 3 b, 3 c to contain the optical signals. A filtration is in this case necessary to avoid polluting the optical transceivers.

As in the version with radiofrequency transmission/reception, the computers or equipment items 210 can be standardized and incorporated simply in the enclosure.

The beams for transmission/reception can be produced in visible light, infrared or ultraviolet. The optical transceivers of the computers are, just like the antennas of the radiofrequency system, inserted into the ventilation tubes 3, 3 a, 3 b, 3 c through apertures dimensioned to oppose the passage of ambient electromagnetic waves.

The invention is not limited to the examples represented and it is for example possible to combine a radiofrequency network and an optical network in the context of the invention. 

1-16. (canceled)
 17. An electrical enclosure provided with an interconnection system for equipment items accommodated in the enclosure, wherein the interconnection system comprises at least one waveguide forming part of a framework of the enclosure, said waveguide being provided with holes arranged facing housings to accommodate said equipment items, said holes being dimensioned to shield passage of wireless communication radiofrequency waves transmitted by said waveguide and to shield external waves.
 18. The electrical enclosure as claimed in claim 17, wherein said equipment items are computers.
 19. The electrical enclosure as claimed in claim 17, wherein said waveguide is configured to serve as a ventilation duct for said equipment items of the enclosure with at least some of said holes providing a passage for air.
 20. The electrical enclosure as claimed in claim 17, further comprising invariant interfaces for said equipment items arranged in the enclosure.
 21. The electrical enclosure as claimed in claim 17, wherein said waveguide is configured to serve as at least one of a grounding link and a functional current return element for said equipment items which are linked thereto.
 22. The electrical enclosure as claimed in claim 17, further comprising a mechanical supporting structure comprising at least some metallic elements configured to serve as conductors to supply an electrical power to said equipment items.
 23. The electrical enclosure as claimed in claim 22, wherein connections between said metallic conductor elements and said equipment items are made by flat contacts.
 24. The electrical enclosure as claimed in claim 17, wherein the interconnection system comprises an architecture based on a standardized topology and on communication protocols of a digital network type.
 25. The electrical enclosure as claimed in claim 24, wherein the interconnection system comprises transceivers provided with antennas inserted into at least some of said holes of the waveguides to link said equipment items to a network.
 26. The electrical enclosure as claimed in claim 25, wherein the transceivers are identical for all said equipment items of the enclosure such that their connection to the network is an invariant.
 27. The electrical enclosure as claimed in claim 17, wherein wired links to remote equipment items arranged in an aircraft are grouped together at an input/output equipment enclosure, the input/output equipment enclosure comprises a router for a wireless link.
 28. The electrical enclosure as claimed in claim 17, further comprising shelves configured to serve as said waveguide.
 29. The electrical enclosure as claimed in claim 28, wherein the shelves are divided into at least two hollow sections, at least one first section is configured to supply cold air to said equipment items borne by the enclosure and to form said waveguide conveying a wireless communication, and at least one second section is configured to extract hot air from said equipment items.
 30. The electrical enclosure as claimed in claim 29, wherein at least one of said two hollow sections supplies an electrical power to said equipment items.
 31. The electrical enclosure as claimed in claim 29, further comprising three hollow sections, a central section configured to supply the cold air to said equipment items borne by the enclosure and to convey the wireless communication, and two lateral sections configured to extract the hot air from said equipment items.
 32. The electrical enclosure as claimed in claim 31, wherein at least one of the two lateral sections supply an electrical power to said equipment items.
 33. The electrical enclosure as claimed in claim 31, wherein the central section is configured to constitute a current return for said equipment items. 